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General WARNING1. All PowerPoint presentation slides and similar materials are
open to misinterpretation and suspect in technical quality without the presenter’s verbal, interaction with an audience.
2. Such presentation materials are not complete, detailed, technical documents and should not be used as such.
3. Data, ideas and conclusions that are extracted can be in error depending on the context or original intent, so that, the presenter or provider of this material is not liable for any inappropriate or erroneous use of the material, or its consequences.
Special Notes• This material has been prepared by Dr. Joseph Bonometti and Mr. Kirk
Sorensen and should not be reproduced or distributed without authorization (Thorium.Trend@neverbox.com or 256-828-6213).
• The work has been prepared as private individuals, not for profit, and as an outside activity not associated with any private organization or governmental agency.
What Fusion Wanted To Be
A systems engineering perspective of a thorium energy economy
October 20, 2009
Dr. Joseph BonomettiAerospace, defense and power technology development manager
Outline1. Highlights of pervious talk:
• Illustrate where the largest global problem actually resides
• Highlight Systems Engineering ideas important to global energy in light of
– What fusion wanted to be!
2. Make Systems Engineering case for LFTR as the best method to exploit thorium and rapidly meet the energy crisis
3. Present a preliminary look at a LFTR Work Breakdown Structure
Assumptions
1. Basic background of thorium2. Idea of LFTR3. Limited Systems Engineering knowledge4. Still need some convincing that thorium is “right”
answer
Energy consumption directly correlates to standard of living and for good reason…
Where largest global problem actually resides…
Address huge
losses
Leaves desirable sources
Phases out poor sources for electricity
More electrical energy diverted to electric
transportation options
Conservation has its limits here
Conceptual Design Stage
It is estimated that at ~ 80 percent of a project’s life-cycle cost is locked in by the initial concept that is chosen.
In a similar manner, all benefits are locked in…
Conceptual Design
The conceptual design sets the theoretical limits.
The conceptual design has the least real-world losses quantified.
Therefore, there MUST be significant inherent advantages to avoid erosion of all the benefits.
“One can not figure to add margin and be assured an advantage over the existing concept, if there is no inherent, and thus untouchable, growth factor.”
Conceptual Design Selection Criteria:
Conventional Nuclear TechnologyPros
• High power-density source• Availability of massive amounts
of energy• No green house emissions• Minimal transportation costs• Low $/kW baseload supply
Cons• Safety fears• High capital costs• Proliferation & terrorist target• Long term waste disposal• Uranium sustainability• Unsightly, bad reputation
~1/3 of CO2 comes from electricity production
Inherently nuclear power produces essentially no CO2
Power Density & Efficiency Why is it important?
• Land usage– cost of the land (lost opportunity for its use)– loss of natural environment
• Flexibility in relocation– minimal infrastructure expense– lower transportation cost– recoup investment should site be closed
• Environment independent– weather, temperature, under/over/no water,
even seismic effects are easily minimize– lower cooling requirements (air or water)
• Manufacturing costs– multiple unit production– reduced material costs– effective human-size operations
• Maintenance costs– less manpower intensive– minimal parts and size
“Smaller”:It is not just for convenience, but essential to reducing costs
Power Generation Resource Inputs• Nuclear: 1970’s vintage PWR, 90%
capacity factor, 60 year life [1]– 40 MT steel / MW(average)– 190 m3 concrete / MW(average)
• Wind: 1990’s vintage, 6.4 m/s average wind speed, 25% capacity factor, 15 year life [2]
– 460 MT steel / MW (average)– 870 m3 concrete / MW(average)
• Coal: 78% capacity factor, 30 year life [2]– 98 MT steel / MW(average)– 160 m3 concrete / MW(average)
• Natural Gas Combined Cycle: 75% capacity factor, 30 year life [3]
– 3.3 MT steel / MW(average)– 27 m3 concrete / MW(average) Recent
increase in natural gas plants
Cost of:
• materials• labor• land• tools• etc…
Distance from end user, prime real estate, energy intensity, etc…
What is LFTR?Liquid Fluoride Thorium Reactor or LFTR (pronounced “Lifter”) is a specific fission energy technology based on thorium rather than uranium as the energy source. The nuclear reactor core is in a liquid form and has a completely passive safety system (i.e., no control rods). Major advantages include: significant reduction of nuclear waste (producing no transuranics and ~100% fuel burnup), inherent safety, weapon proliferation resistant, and high power cycle efficiency.
– The best way to use thorium.– A compact electrical power source.– Safe and environmentally compatible energy.– A new era in nuclear power.
What fusion promises someday…
Fundamental Process & Objectives
MinimumU233Core
Replacement U233 Products
Cold InHot Out
Drives Turbines
BlanketThorium In
233P
a
Intermediate Storage
Safety &Compact/
Mobile
Timeliness & Covers
Energy Gap
Cost Effective
& GridInterfacing
Proliferation& Waste
Reduction
• Liquid Fluoride Thorium Reactor …– A type of nuclear reactor where the nuclear fuel is in a liquid
state, suspended in a molten fluoride-based salt, and uses a separate fluid stream for the conversion of thorium to fissionable fuel to maintain the nuclear reaction.
• It is normally characterized by:– Operation at atmospheric pressure– High operating temperatures (>>600K)– Chemical extraction of protactinium-233 and reintroduction of its
decay chain product, uranium-233– Thermal spectrum run marginally above breakeven– Closed-Cycle Brayton power conversion
“It is the melding of the nuclear power and nuclear processing industries; surprisingly, something that does not occur naturally.”
Technical Details
No Long Term Radioactive StorageEasy Site CleanupSmall Land UseMinimize Waste HeatDisaster/Weather Tolerant
Environment
Easily MovedAdaptable To Other MissionsAir & Water Cooling
Flexibility
100 kW to 1 GW UnitsMultiple Unit OperationMinimal Physical SizeLoad Following Operation
Scalability
Low Capital InvestmentLow Fuel PriceMinimal End-of-Life ExpenseLow MaintenanceLong LifeNominal TransportationMinimal Legal/Site Risk
Cost
Dense Energy SourceHigh-grade Electric Power OutputMinimal Internal Energy ConsumptionHigh Thermodynamic Efficiency
Power
Proliferation ResistanceEasy TrackingUnattractive Terrorist TargetGrid StabilityEasy Restart
Security
No Radiation ReleaseQuick ShutdownMinimize Public ExposurePassive Heat RemovalSimple & Inherent
Safety
LFTR Inherent Advantages
Homogeneous MixingExpandableNo Separate CoolantDrainable
Liquid Core
AbundantFissileChemically Distinct
Thorium
Ionic Chemical StabilityRoom Temperature SolidHigh TemperatureLow Vapor Pressure
Fluoride Salt
Minimal Fissile InventoryNo Fuel FabricationExtraction of PoisonsExtraction of Valuables
Internal Processing
High Efficiency RecuperatorAIr or Water Heat RejectionVariable Inlet Pressure
Closed-Cycle Brayton
LFTR
SecurityFlexibility Scalability
Environment
CostSafetyDesired Goals
Power
LFTR Work Breakdown Structure
WBS Primer
• System Engineering Tool– Usually one of the first tasks completed– Define the project parts, i.e., ‘products’– Important that it identifies products:
• Largest or costly• Most complex• Critical to investigate (known or unknown)
• First place to layout the interrelationships of pieces that make up the system
• Sets the tone on how the System Engineer wants to “orchestrate” the game plan
• Used by Program management, budget, contract and business office personnel as a convenient shopping list to track work, designate funding, allocate resources, etc…
Draft LFTR WBS
Level 1:
• LFTR Prototype Development Reactor– Non-production– Full-scale mobile unit class– Not optimized for efficiency or minimum
volume
Level 2 and beyond are engineering driven
LFTR WBS
• 2.0 Systems Engineering
• 3.0 Reactor
• 4.0 Power Conversion
• 5.0 Thermal Management
• 6.0 Chemical Process Engineering
• 7.0 Proliferation Security
• 8.0 Project Management
“Orchestra Conductor”
“Main Instruments”
“Sheet Music”
“Orchestra Pit”
What Fusion Wanted To BeFusion promised to be:1. Limitless (sustainable)
energy
2. Safe
3. Minimum radioactive waste
4. Proliferation resistant
5. Environmentally friendly
6. Power dense
7. Little mining, transportation, or land use
8. Low cost
Thorium can be:1. Near limitless (sustainable for
100s of years) with supplies easily found throughout the solar system
2. In liquid form (e.g. LFTR), thorium has analogous safety
3. Limited radioactive wastes makes thorium comparable
4. Equivalent proliferation resistant
5. As environmentally friendly
6. Much greater power density
7. Equivalent mining, transportation & land use
8. Much lower cost
Summary
• Think about the entirety of the global energy crisis:– Required Resource Intensity– Diminishing Returns (producing the next 10 Quads….)– Power Density relation to cost, applicability, flexibility, etc.– The speed to produce on the order of 100 Quads worldwide– Vulnerabilities (storms, attacks, environment)
• Systems Engineering is the “next step”– What needs to be done– Order of tasks– Identify what is dominant
www.energyfromthorium.com
Hyperlinks
Can Nuclear Reactions be Sustained in Natural Uranium?
Not with thermal neutrons—need more than 2 neutrons to sustain reaction (one for conversion, one for fission)—not enough neutrons produced at thermal energies. Must use fast neutron reactors.
Return
Yes! Enough neutrons to sustain reaction produced at thermal fission. Does not need fast neutron reactors—needs neutronic efficiency.
Can Nuclear Reactions be Sustained in Natural Thorium?
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Liquid Core Advantages
Safety
No Hot Spots
EnvironmentCostFlexibility
No Fuel Shutdowns
EnvironmentCost
Complete Fuel Burnup
Homogeneous Mixing
Safety
Load Following
ScalabilityFlexibility
Easy Core Design
CostSecurity
No Control Rods
SafetyCost
Negative Temp Coef.
Expandable
SafetyCost
Less Complexity
SafetySecurity
Reduced Risk
PowerCostFlexibility
Better Thermodynamics
No Separate Cooling
SafetyCost
Passive (gravity) Shutdown
Safety
Passive Heat Removal
CostFlexibility
Easy Core Replacement
SafetyCostFlexibility
Stop & Restart Operation
Drainable
Passive Decay Heat Removalthru Freeze Valve
Secondary Containment DrumRestart Pump
Passive Heat Removal Container
Liquid Reactor Core
Restart Heaters
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Thorium Advantages
Cost
Easy Mining & Processing
PowerCostScalability
Sustainable Supply
SecuritySafety
Fewer World Quarrels
Abundant
CostFlexibility
Easy Transportation
SecurityCost
Less Terrorist Interest
SecuritySafety
Low Proliferation
SafetyCostScalability
Cannot Explode
Fertile Not Fissile
CostFlexibilityPower
Easily Processed
SafetySecurityPower
Continual Removal of Elements(Protactinium, Uranium, Etc.)
Cost
Easily Detected
Chemically Distinct
Uranium Fuel Cycle vs. Thorium1000 MW of electricity for one year
250 tonsNatural uranium
35 tonsEnriched Uranium(Costly Process)
215 tonsdepleted uranium
-disposal plans uncertain
Uranium-235 content is “burned” out of the fuel;
some plutonium is formed and burned
35 tons Spent FuelYucca Mountain (~10,000 years)• 33.4 t uranium-238• 0.3 t uranium-235• 0.3 t plutonium• 1.0 t fission products
1 tonNatural Thorium
Thorium introduced into blanket of fluoride reactor;
completely converted to uranium-233 and “burned”
1 TonFission products;
no uranium, plutonium, or
other actinides
Within 10 years, 83% of fission products are
stable and can be partitioned and sold.
The remaining 17% fission products go to geologic isolation for
~300 years.
800,000 tons Ore
200 tons Ore
Is the Thorium Fuel Cycle a Proliferation Risk?
• When U-233 is used as a nuclear fuel, it is inevitably contaminated with uranium-232, which decays rather quickly (78 year half-life) and whose decay chain includes thallium-208.
• Thallium-208 is a “hard” gamma emitter, which makes any uranium contaminated with U-232 nearly worthless for nuclear weapons.
• There has never been an operational nuclear weapon that has used U-233 as its fissile material, despite the ease of manufacturing U-233 from abundant natural thorium.
• U-233 with very low U-232 contamination could be generated in special reactors like Hanford, but not in reactors that use the U-233 as fuel.
U-232 Formation in the Thorium Fuel Cycle
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Fluoride Salt Advantages
Safety
Insensitive to Radiation Damage
Environment
High Bond Strength
EnvironmentSecurity
Compatibility WithDifferent Mixtures
Ionic Chemical Stability
Safety
Nonvolatile When Cool
FlexibilitySafety
Leak Resistant
CostSecurity
Easy shipping and Handling
SafetyCost
Easy Spill Cleanup
Room Temperature Solid
PowerCost
Good Thermodynamics
SafetyFlexibility
No Temperature Limitations
CostSafety
Corrosion Resistance
High Temperature
SafetyCost
Gas Buildup Readily Comes Out
SecurityCost
Salt Components Remain
Low Vapor Pressure
Radiation Damage Limits Energy Release• Does a typical nuclear reactor extract
that much energy from its nuclear fuel?– No, the “burnup” of the fuel is limited by
damage to the fuel itself.
• Typically, the reactor will only be able to extract a portion of the energy from the fuel before radiation damage to the fuel itself becomes too extreme.
• Radiation damage is caused by:– Noble gas (krypton, xenon) buildup
– Disturbance to the fuel lattice caused by fission fragments and neutron flux
• As the fuel swells and distorts, it can cause the cladding around the fuel to rupture and release fission products into the coolant.
Ionically-bonded fluids are impervious to radiation
• The basic problem in nuclear fuel is that it is covalently bonded and in a solid form.
• If the fuel were a fluid salt, its ionic bonds would be impervious to radiation damage and the fluid form would allow easy extraction of fission product gases, thus permitting unlimited burnup.
Corrosion Resistance at Temperature• Fluoride salts are fluxing agents that
rapidly dissolve protective layers of oxides and other materials.
• To avoid corrosion, molten salt coolants must be chosen that are thermodynamically stable relative to the materials of construction of the reactor; that is, the materials of construction are chemically noble relative to the salts.
• This limits the choice to highly thermodynamically-stable salts.
• This table shows the primary candidate fluorides suitable for a molten salt and their thermo-dynamic free energies of formation.
• The general rule to ensure that the materials of construction are compatible (noble) with respect to the salt is that the difference in the Gibbs free energy of formation between the salt and the container material should be >20 kcal/(mole ºC).
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Internal Processing Advantages
CostFlexibility
Small Size/Less Shielding
EnvironmentCostFlexibility
Low Fuel Cost
SecurityCostEnvironment
Proliferation Resistance
EnvironmentCost
Less Clean Up
Minimal Fissile Inventory
CostSecurity
No Fuel Infrastructureor Bureaucracy
CostSecurity
Less Terroristor Proliferation Threats
CostSecurity
No Transportation
CostSafetyScalabilityFlexibility
No Fuel Inspections
No Fuel Fabrication
SafetyCost
Reduced Contamination
CostSecurity
Smaller Core Size
EnvironmentCost
Less Permanent Waste
SafetyCost
Better Reactor Control
Extraction of Poisons
CostFlexibility
Radioactive Products
SafetyCostFlexibility
Smaller Core Size
CostFlexibility
Rare Earth Metals
Extraction of Valuables
LFTR Processing Details
FluorideVolatility
VacuumDistillation
Uranium Absorption-Reduction
232,233,234UF6
7LiF-BeF2-UF4
233UF6
FissionProductWaste
HexafluorideDistillation
FluorideVolatility
7LiF-BeF2
“Bare” Salt
Pa-233Decay Tank
Metallic thorium
MoF6, TcF6, SeF6,RuF5, TeF6, IF7,
Other F6
Fuel SaltxF6
Core
Blanket
Two-Fluid Reactor
Bism
uth
-me
tal
Re
du
ctive
Extra
ction
Co
lum
n
Molybdenum and Iodine for Medical Uses
Fertile Salt
Recycle Fertile Salt
Recycle Fuel Salt
Pa
Return
Closed-Cycle Brayton Advantages
FlexibilityCost
Location Independence
PowerEnvironment
Best Match to Sink Temperature
Air or Water Heat Rejection
PowerCost
High Thermodynamic Efficiency
CostPower
Jet AircraftTurbo Machinery Technology
High Efficiency Recuperator
ScalabilityCost
Smaller Physical Size
ScalabilityFlexibility
Match Optimum GasThermodynamic Properties
Cost
Cleaner WithLess Maintenance
Variable Inlet Pressure
• Cost– Low capital cost thru small facility and compact power conversion
• Reactor operates at ambient pressure• No expanding gases (steam) to drive large containment• High-pressure helium gas turbine system
– Primary fuel (thorium) is inexpensive
– Simple fuel cycle processing, all done on site
Cost advantages come from size and complexity reductions
GE Advanced Boiling Water Reactor (light-water reactor)
Fluoride-cooled reactor with helium gas turbine power conversion system
Reduction in core size, complexity,
fuel cost, and turbomachinery
Thorium Reactor could cost 30-50% Less(Cost Effective & Grid Interfacing)
• No pressure vessel required• Liquid fuel requires no expensive fuel fabrication and qualification• Smaller power conversion system - Uses higher pressure (2050 psi)• No steam generators required• Factory built-modular construction - Scalable: 100 KW to multi GW• Smaller containment building needed - Steam vs. fluids• Simpler operation - No operational control rods - No re-fueling shut down - Significantly lower maintenance - Significantly smaller staff• Significantly lower capital costs• Lower regulatory burden• No grid interfacing costs: - Inherent load-following - No power line additions/alterations - Minimum line losses - Plant sized by location/needs
Plant Size Comparison: Steam (top) vs. CO2 (bottom) for a 1000 MWe plant
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